Abstract: A method for providing resource allocation in a communication network includes identifying at least two broadcast zones for receiving broadcast services in the communication network and generating a first index based on a relative relationship among the at least two broadcast zones. The first index includes information indicative of whether a first broadcast zone overlaps with at least one other broadcast zone. The method further includes generating a second index based on the relative relationship among the at least two broadcast zones; assigning at least one identifier to each of the at least two broadcast zones based on the first index and the second index; and enabling data transmissions to the at least two broadcast zones based on the assigned identifiers and using the at least one communication resource associated with the identifiers. The second index may include information indicative of a number of broadcast zones overlapped with the first broadcast zone.

Abstract: An edge type back light module and a display device using the same are provided. The edge type back light module includes a light guide plate (LGP), a light source and a frame. The LGP has a light-receiving surface, a light-emitting surface and a light-reflecting surface opposite to the light-emitting surface. The light-emitting surface faces the display panel. The light source is adjacent to the light-receiving surface for emitting a light. The frame has a frame surface and a light guide portion. After a portion of the light contacts the light guide portion, the light guide portion disposed on the frame surface guides the portion of the light to be emitted from the light-emitting surface. A predetermined angle is contained between the outgoing direction of the portion of the light emitted from the light-emitting surface and the normal direction of the light-emitting surface.

Abstract: A backlight module includes a light source and a light guide plate. The light guide plate includes a light-receiving surface next to a light source, a light-emitting surface, and a light-reflecting surface oppose to the light-emitting surface. A plurality of notches are formed on the light-reflecting surface, and each notch has a first inner surface facing the light source and a second inner surface back to the light source and opposite to the first inner surface. The inclination angle of the first inner surface with respect to the light-reflecting surface is no more than 35 degrees.

Abstract: The invention discloses a light guide plate structure. The light guide plate structure includes a light-receiving surface, a light-emitting surface and a light-reflecting surface. The light-receiving surface receives emitting light from at least a light source, and the light propagating in the light guide plate exits through the light-emitting surface. The light-reflecting surface is opposite to the light-emitting surface for guiding the light that passes through the light-receiving surface to the light-emitting surface. The light-emitting surface and/or the light-reflecting surface include at least a composite structure. The composite structure includes a primary structure and a secondary structure where the secondary structure is disposed to a side of the primary structure.

Abstract: An alternating current light-emitting device includes a substrate, an alternating current microdie light-emitting module, and a conductive structure. The alternating current microdie light-emitting module is formed on the substrate and has at least two microdies and a concave portion disposed between the two microdies. Each of the microdies has at least one active layer. The conductive structure electrically connects the microdies and thereby enables the active layers of the microdies to take turns to emit light during positive and negative half cycles of alternating current. The conductive structure is formed in the concave portion and covers an insulator. The present invention prevents undue open circuits but enhances yield.

Abstract: A back light module includes a light guide plate, a light emitting unit, and a prism sheet. The light guide plate has a bottom surface, a light output surface opposite to the bottom surface, a light incident surface connected to the bottom surface and the light output surface, and multiple cambered diffusion portions on the light output surface. The cambered diffusion portions are paralleled to one another. Each cambered diffusion portion has a cambered surface. The light emitting unit is disposed near the light incident surface. The prism sheet is disposed over the cambered diffusion portions and has multiple linear prisms protruding toward the light guide plate. The linear prisms are paralleled to one another. The stretching direction of the linear prisms is substantially perpendicular to that of the cambered diffusion portions. Backlight uniformity can be improved and the viewing angle of the backlight system also increases in specific direction.

Abstract: An alternating current light-emitting device includes a substrate, an alternating current microdie light-emitting module, and a conductive structure. The alternating current microdie light-emitting module is formed on the substrate and has at least two microdies and a concave portion disposed between the two microdies. Each of the microdies has at least one active layer. The conductive structure electrically connects the microdies and thereby enables the active layers of the microdies to take turns to emit light during positive and negative half cycles of alternating current. The conductive structure is formed in the concave portion and covers an insulator. The present invention prevents undue open circuits but enhances yield.

Abstract: A backlight module includes a light source and a light guide plate. The light guide plate includes a light-receiving surface next to a light source, a light-emitting surface, and a light-reflecting surface oppose to the light-emitting surface. A plurality of notches are formed on the light-reflecting surface, and each notch has a first inner surface facing the light source and a second inner surface back to the light source and opposite to the first inner surface. The inclination angle of the first inner surface with respect to the light-reflecting surface is no more than 35 degrees.

Abstract: A light guide plate (LGP) with auxiliary light guide structures is presented, wherein the top or bottom surface has a plurality of auxiliary light guide structures and light guide patterns, and wherein the dihedral angle between the tangent plane of the auxiliary light guide structure and the reference plane is less than 40 degrees. And the surfaces of the light guide pattern are rough surfaces. Together with the functions of the auxiliary light guide structures and the light guide patterns, the light is guided and emitted out of the LGP, and then the probability of the light emitted out of the LGP is increased after the light is scattered or reflected by the light guide patterns.

Abstract: A backlight module includes a light guide plate, a bar member, and two point light sources. The bar member is connected to one side of the light guide plate with a slot being formed between them. The bar member has a light emitting surface facing the light receiving surface of the light guide plate and a light reflecting surface opposite to the light emitting surface, and the light emitting surface and the light receiving surface are spaced apart from each other by the slot. The light receiving surface of the light guide plate and the light emitting surface of the bar member are both bent toward or away from the light reflecting surface.

Abstract: A high-efficiency matrix-type LED device comprises an epitaxial wafer on which a plurality of independently insulated LEDs are formed by a method of manufacturing integrated circuits; and a conducting line mounted on each one of the LEDs by an evaporation method for forming a large-sized matrix-type LED unit capable of increasing brightness, simplifying manufacturing procedure, and saving manufacturing cost effectively. In addition, a sub-mount having a two-way Zener diode embedded therein is applied to the matrix-type LED unit. By mounting the matrix-type LED unit on the sub-mount, the two-way Zener diode can protect the LEDs against damage from electrostatic discharge (ESD) so as to increase lifetime of LEDs.

Abstract: A LED-based light emitting device having integrated rectifier circuit driven directly by an AC voltage and a related fabrication method is provided herein. The light emitting mainly contains a lower substrate and an upper substrate. The lower substrate has a built-in rectifier circuit and appropriate electrical contacts of the rectifier circuit are exposed on the top surface of the lower substrate. The upper substrate contains multiple LEDs arranged in an N×M array and the LEDs are all electrically insulated from each other. Metallic plating techniques are applied to establish electrical connection between these LEDs so that they jointly form a circuit matching the rectifier circuit on the lower substrate. The two substrates are faced towards each other and metallic bumps are applied to connect the LED circuit on the upper substrate to the rectifier circuit on the lower substrate, completing a fully function light emitting device.

Abstract: A light-guide plate and its light-guide structures that are formed at the plate body of the light-guide plate in a concave configuration, a bottom side of the light-guide facet of the light-guide structures that face to the light source approximately presents an arc-like shape. The arc-like shape makes the light after deflecting have the effect of diffusion for a certain extent. These light-guide structures present a sparse-to-dense distribution along the direction that is away from the light source. The arc angles of the bottom side of the light-guide structures present a large-to-small configuration along the direction that is away from the light source such that the whole brightness of the light-guide plate is uniform.

Abstract: A transflective brightening plate and a double-face lighting backlight module to which the transflective brightening plate is applied. The transflective brightening plate includes multiple brightening structures on one face of a substrate. The brightening structures are light-guiding structures as micro-prisms. A transflective coating is disposed on the other face of the substrate. The light is partially reflected by the transflective coating and partially penetrates through the transflective coating.

Abstract: A double-sided light emitting backlight module is mounted between two liquid crystal display modules and includes at least one light source, a lighting photoconductive board, and at least one brightness enhancement film. Thus, the P light passes through the brightness enhancement film and the S light is reflected by the brightness enhancement film and is transformed to a mixed light of the P light and S light. Thus, the backlight module can prevent the lower polarized plate of the liquid crystal display module from absorbing the S light of all of the light beams of the light source, thereby relatively increasing the usage of the light source, and thereby enhancing the brightness of the liquid crystal display module.

Abstract: A backlight module structure is including a photoconductive element. The top of the photoconductive element has an outgoing face formed with numerous microstructures. An optical transforming layer is overlaid on the outgoing face of the photoconductive element between the outgoing face and the liquid crystal module. A solid powder material is mixed with a polymer binder and adhered to a transparent substrate to form the optical transforming layer. The solid powder material includes at least a lighting material.

Abstract: Photoconductive structure of backlight module includes a photoconductive board, a light source, a reflecting board and a brightening film. One of top face and bottom face of the photoconductive board is formed with multiple photoconductive patterns which are concentric arches centered at the light source. The reflecting board is disposed on one face of the photoconductive board, while the brightening film is disposed on the other face of the photoconductive board. One of the top face and bottom face of the brightening film is formed with multiple focusing patterns arranged in the same aspect as the photoconductive patterns of the photoconductive board. Under action of the focusing patterns and the photoconductive patterns, the light beam projected from the light source is concentrated and goes out from the photoconductive board in the direction of the normal line of the photoconductive board.

Abstract: A backlight module structure is including a photoconductive element. The top of the photoconductive element has an outgoing face formed with numerous microstructures. An optical transforming layer is overlaid on the outgoing face of the photoconductive element between the outgoing face and the liquid crystal module. A solid powder material is mixed with a polymer binder and adhered to a transparent substrate to form the optical transforming layer. The solid powder material includes at least a lighting material.

Abstract: A method for manufacturing microlens light guide, which mainly includes forming patterns, in a concave or convex shape, on a plastic or wax mold substrate by mechanical processing or non-traditional processing, plasticizing the patterns to microlens patterns, as a master mold for later use, by thermal flow, electroforming to make mold core for later use, and finally injection molding to make microlens light guide.

Abstract: A face light source module structure including more than one light sources and a light guiding board. One face of the light guiding board adjacent to the light sources is defined as an incoming face. One face of the light guiding board opposite to the incoming face is defined as a first reflective face plated with a mirror face coating. One face of the light guiding board adjacent to the liquid crystal module is defined as an outgoing face. The face opposite to the outgoing face is defined as a second reflective face. The outgoing face and the second reflective face are respectively evaporated with two anti-reflection coatings. The anti-reflection coating of the outgoing face has a leakage design. After going into the light guiding board, the light of the light sources is totally reflected to project through the leakage design of the outgoing face toward the liquid crystal module.